Abstract: A hanging drop plate and a method of cultivating cells or of producing molecular aggregates in at least one liquid volume that adheres to a drop contact area of such a hanging drop plate. The hanging drop plate has a body with a first surface and a second surface that is essentially coplanar to the first surface. The second surface has a drop contact area for adherently receiving a liquid volume. The drop contact area is distinguished from a surrounding area by a relief structure that prevents spreading of the liquid volume on the second surface of the body. The body has at least one conduit that mouths into the drop contact area from the direction of the first surface of the body. A liquid volume is applied to the drop contact area through a communicating conduit. Cells and/or molecules can be introduced into this liquid volume.

Abstract: Developing heart valves are exposed to dynamic strains by applying a dynamic pressure difference over the leaflets. The flow is kept to a minimum, serving only as a perfusion system, supplying the developing tissue with fresh nutrients. Standard heart valves were engineered based on B trileaflet scaffolds seeded with cells isolated from the human saphenous vein. Tissue compaction is constrained by the stent, inducing increasing pre-strain in the tissue. The dynamic strains the tissues are exposed to via the dynamic pressure difference, are estimated using finite element methods based on the mechanical properties of the neo-tissue, in order to get inside into the strain distribution over the leaflet.

Abstract: Developing heart valves are exposed to dynamic strains by applying a dynamic pressure difference over the leaflets. The flow is kept to a minimum, serving only as a perfusion system, supplying the developing tissue with fresh nutrients. Standard heart valves were engineered based on B trileaflet scaffolds seeded with cells isolated from the human saphenous vein. Tissue compaction is constrained by the stent, inducing increasing pre-strain in the tissue. The dynamic strains the tissues are exposed to via the dynamic pressure difference, are estimated using finite element methods based on the mechanical properties of the neo-tissue, in order to get inside into the strain distribution over the leaflet.

Abstract: In one aspect the invention provides a bioreactor system for the production of tissue prostheses. The system includes a bioreactor, a culture medium reservoir coupled to the bioreactor by a first conduit and a second conduit, a pump operable to pump fluid into and draw fluid out of a pumping chamber defined in the bioreactor to generate a pulsatile flow of culture medium through the reservoir and bioreactor via said first and second conduits, one or more flow meters operable to generate flow rate signals representative of the rate of culture medium flow through one or both of said first and second conduits, and a controller arranged to receive said flow rate signals from said one or more flow meters and to control the pump means in response to said received flow rate signals to provide a desired rate of culture medium flow.

Abstract: In one aspect the invention provides a bioreactor system for the production of tissue prostheses. The system includes a bioreactor, a culture medium reservoir coupled to the bioreactor by a first conduit and a second conduit, a pump operable to pump fluid into and draw fluid out of a pumping chamber defined in the bioreactor to generate a pulsatile flow of culture medium through the reservoir and bioreactor via said first and second conduits, one or more flow meters operable to generate flow rate signals representative of the rate of culture medium flow through one or both of said first and second conduits, and a controller arranged to receive said flow rate signals from said one or more flow meters and to control the pump means in response to said received flow rate signals to provide a desired rate of culture medium flow.

Abstract: The present invention relates to a biodegradable scaffold for a prosthetic implant, such as a prosthetic vessel and/or a prosthetic heart valve. The implantable prosthetic further comprises a biological tissue-like matrix. The present invention further provides methods of assembling or manufacturing a biodegradeable prosthetic implant using pre-formed jig components.

Abstract: The present invention relates to methods for the in vitro production of mammalian tissue replacements using substantially pure populations of isolated non-embryoblastic fetal cells having the capacity to differentiate into the cell type(s) that form(s) the native tissue. The tissue replacements engineered by the methods of the present invention are especially useful for the repair of non-functional or malfunctional cardiovascular structures in patients suffering from congenital cardiovascular disorders.

Abstract: Developing heart valves are exposed to dynamic strains by applying a dynamic pressure difference over the leaflets. The flow is kept to a minimum, serving only as a perfusion system, supplying the developing tissue with fresh nutrients. Standard heart valves were engineered based on B trileaflet scaffolds seeded with cells isolated from the human saphenous vein. Tissue compaction is constrained by the stent, inducing increasing pre-strain in the tissue. The dynamic strains the tissues are exposed to via the dynamic pressure difference, are estimated using finite element methods based on the mechanical properties of the neo-tissue, in order to get inside into the strain distribution over the leaflet.